Introduction
Aging is defined as the accumulation of diverse deleterious changes in cells and tissues (1). It is commonly associated with a reduction in physiological functions, and is closely related to apoptosis. In biology, the state or process of aging is known as senescence. It occurs at the level of the organism (organismal senescence), as well as at the level of individual cells (cellular senescence). At the individual cell level there are two types of senescence, replicative and stress-induced premature senescence (SIPS). Genetic and environmental manipulations have revealed that aging is regulated by specific pathways, involved in hormonal signaling, nutrient sensing and signaling, mitochondria and ROS signaling and genome surveillance (2). However, the question of whether all these signaling pathways exert their effects separately, or involve one or more junction co-regulators among these signaling pathways in the aging process remains to be determined.
Chinese herbs have been widely applied in the field of medicine as anti-aging drugs because of their few side-effects (3,4). The plant species Lycium barbarum (L. barbarum) belongs to the family of Solanaceae, and its fruit or extract has been regarded in Chinese pharmacopoeia as a superior-grade medicine for the modulation of body immunity (5–7). The effects of L. barbarum are attributed to the polysaccharides (LBPs) it contains, which can upregulate both innate and adaptive immune responses (8,9). It has been shown that LBPs can protect neurons from β-amyloid peptide neurotoxicity (10,11), and from neuronal death, glial activation and oxidative stress in a murine retinal ischemia/reperfusion model (12,13).
The tumor suppressor gene p53 has been known to play an important role in the induction of cell cycle arrest and apoptosis (14). In a recent study, LBPs were found to stimulate the proliferation of MCF-7 cells via the ERK pathway, which may be associated with the p53 pathway (15). Although findings of previous studies have demonstrated the beneficial effects of LBPs on the health of humans and animals (16,17), to the best of our knowledge, there have been scarce studies that systematically investigate the signaling pathway(s) via which LBPs exert these beneficial effects, especially in zebrafish, an excellent model for studying angiogenesis, senescence, and toxicity responses (18–21). In this study, we examined senescence during the early development stages of zebrafish, cell apoptosis, and senescence-associated gene expression upon treatment with LBPs from the Chinese herb L. barbarum in the zebrafish model, in order to investigate the effects of this herb and identify the related signaling pathway(s) potentially involved in anti-aging processes.
Materials and methods
Materials and animals
Purified L. barbarum polysaccharides (LBPs) were purchased from Shanxi Undersun Biomedtech Co., Ltd. (Xi’an, Shaanxi, China) and an extract was prepared using the method of Luo et al (22). Zebrafish were maintained in standard fish facility conditions with a 14:10 h light/dark cycle and fed with living brine shrimp twice per day. The water temperature was maintained at 28°C. The study was approved by the ethics committee of Ocean University of China (Qingdao, China).
Embryo treatment and image collection
Embryos at 8 hours post-fertilization (hpf) were placed into a 24-well microplate (Millipore Co., Bedford, MA, USA). Thirty embryos were continuously exposed to varying concentrations of LBPs (0, 1, 2, 3 and 4 mg/ml) for 3 days (d). LBPs were renewed daily. Each treatment with an LBP concentration was repeated three times and the standard deviation was calculated. To collect images of embryo phenotypes, treated and non-treated embryos were anesthetized with 0.2 mg/ml tricaine (3-aminobenzoic acid ethylester; Sigma-Aldrich, St. Louis, MO, USA) and embedded in methylcellulose.
Senescence associated-β-galactosidase (SA-β-gal) assay
Embryos of 72 hpf were fixed in 4% paraformaldehyde in phosphate-buffered saline, at 4°C overnight. Staining of SA-β-gal and quantifications were performed according to the method of Kishi et al (23).
In vivo detection of cell death
For the in vivo detection of cell death, 2 day-old embryos were incubated in 5 mg/ml acridine orange stain (AO; Sigma-Aldrich) in zebrafish embryo medium [NaCl, 5.03 mM; KCl, 0.17 mM; CaCl2·2H2O, 0.03 mM; MgSO4·7H2O, 0.03 mM; methylene blue, 0.1% (w/v)] and kept in the dark for 15–30 min at 28°C, then rinsed thoroughly 8 times with egg water. Stained embryos were anesthetized with MESAB (0.5 mM 3-aminobenzoic acid ethyl ester, 2 mM Na2HPO4) and mounted in a depression slide for observation using methylcellulose. They were then visualized using a fluorescence microscope (AZ100, Nikon, Tokyo, Japan) and images were captured for <60 sec (the signal is quenched after 60 sec of exposure to fluorescence). Embryos that were not stained with AO were used to determine baseline fluorescence.
Semi-quantitative RT-PCR
Total RNA was extracted from 72 hpf embryos using the TRIzol reagent. Semi-quantitative PCR was performed with an initial incubation for 5 min at 94°C, followed by 22 cycles of incubation at 94°C for 30 sec, 55°C for 30 sec, and 72°C for 30 sec. The primers for amplification of p53 and p21 were the same as in (24): p53 forward/reverse: CTCTCCCACCAACATCCACT/ACGTCCACC ACCATTTGAAC; p21 forward/reverse: CGGAATAAA CGGTGTCGTCT/CGCAAACAGACCAACATCAC. The primers for amplification of Bax, Mdm2, TERT and β-actin were: Bax forward/reverse: GGAGATGAGCTGGAT GGAAAT/ATGACGTGCTCCTGAATGTAG; Mdm2 forward/reverse: GACTACTGGAAGTGTCCCAAAT/GTCCACTCCATCATCTGTTTCT; TERT forward/reverse: GTGTGTGTGTCCTGGGTAAA/CAGCCTGAGGTCTAA GAAGATG; β-actin forward/reverse: CCCAGACATCAG GGAGTGAT/TCTCTGTTGGCTTTGGATT. Subsequently, 10 μl PCR products were loaded into gels for agarose gel electrophoresis.
Statistical analysis
Data are presented as mean ± SD (n=30). Differences between groups were assessed by analysis of variance (ANOVA) and Student’s t-tests. Statistical analyses was carried out using SPSS for Windows, Version 11.5 (SPSS Inc., Chicago, IL, USA).
Discussion
L. barbarum fruits (berries) or extract have been widely used for centuries to balance the ‘Yin’ and the ‘Yang’ in the body (33). The major ingredient of the liquid fraction of these berries, LBPs, has been the object of research focus in studies aiming to identify anti-aging remedies (34) or agents alleviating cellular damage (12,35).
p53, as a central mediator of cellular responses induced in various processes including apoptosis (36), was shown to exert similar effects to ERK during stress induced by DNA damage (37). In MCF-7 cells, LBPs increased the activity of ERK (15). p21 as a regulator of cell cycle progression controlled by the tumor suppressor protein p53, inhibited tumor progression, thus preventing cell proliferation, while inducing cell apoptosis (38). In our study, cell apoptosis was inhibited following treatment with non-toxic doses of LBPs (1–3 mg/ml), as shown by AO staining, the reduced expression of p53 and the increased expression of its negative regulator, Mdm2. A potential explanation for these findings is that the cellular responses triggered by the activated p53 protein (cellular senescence) act as potent barriers against the effects of LBPs.
In this study, we assessed the relevance of one molecular mechanism potentially underlying the effect of LBPs on cellular senescence in a zebrafish model by phenotypic and SA-β-gal assays, in vivo detection of survival rates and expression profiling of genes that related to the p53 signaling pathway during senescence. Zebrafish senescence was alleviated by LBPs via inhibition of cell death and apoptosis in the early development, a reduction in the expression level of p53, p21 and Bax genes and an increase in the expression of Mdm2 and TERT genes. In conclusion, our findings suggest that the anti-aging effects of LBPs are mediated by the p53 signal pathway. The specific targets of LBPs in this pathway may be identified in future studies.